English

Prediction of the SYM-H Index Using a Bayesian Deep Learning Method with Uncertainty Quantification

Instrumentation and Methods for Astrophysics 2024-02-28 v1 Machine Learning

Abstract

We propose a novel deep learning framework, named SYMHnet, which employs a graph neural network and a bidirectional long short-term memory network to cooperatively learn patterns from solar wind and interplanetary magnetic field parameters for short-term forecasts of the SYM-H index based on 1-minute and 5-minute resolution data. SYMHnet takes, as input, the time series of the parameters' values provided by NASA's Space Science Data Coordinated Archive and predicts, as output, the SYM-H index value at time point t + w hours for a given time point t where w is 1 or 2. By incorporating Bayesian inference into the learning framework, SYMHnet can quantify both aleatoric (data) uncertainty and epistemic (model) uncertainty when predicting future SYM-H indices. Experimental results show that SYMHnet works well at quiet time and storm time, for both 1-minute and 5-minute resolution data. The results also show that SYMHnet generally performs better than related machine learning methods. For example, SYMHnet achieves a forecast skill score (FSS) of 0.343 compared to the FSS of 0.074 of a recent gradient boosting machine (GBM) method when predicting SYM-H indices (1 hour in advance) in a large storm (SYM-H = -393 nT) using 5-minute resolution data. When predicting the SYM-H indices (2 hours in advance) in the large storm, SYMHnet achieves an FSS of 0.553 compared to the FSS of 0.087 of the GBM method. In addition, SYMHnet can provide results for both data and model uncertainty quantification, whereas the related methods cannot.

Keywords

Cite

@article{arxiv.2402.17196,
  title  = {Prediction of the SYM-H Index Using a Bayesian Deep Learning Method with Uncertainty Quantification},
  author = {Yasser Abduallah and Khalid A. Alobaid and Jason T. L. Wang and Haimin Wang and Vania K. Jordanova and Vasyl Yurchyshyn and Huseyin Cavus and Ju Jing},
  journal= {arXiv preprint arXiv:2402.17196},
  year   = {2024}
}

Comments

28 pages, 8 figures

R2 v1 2026-06-28T15:01:24.569Z